i think the gravity pulls it or the carbon diaxode change to air
The list of choices posted with the question doesn't include anything that fits that description. It sounds something like a "star", but in a star, it would be "fusion", not "fission".
A nebula IS a cloud of dust and gas loosely held together by gravity.
A small quantity of dust and gas will have a small gravitational force. The idea is that, to form a solar system (or a group of solar systems), a large amount has to come together; and in that case, it would have a significant mass, and significant forces would be acting.A small quantity of dust and gas will have a small gravitational force. The idea is that, to form a solar system (or a group of solar systems), a large amount has to come together; and in that case, it would have a significant mass, and significant forces would be acting.A small quantity of dust and gas will have a small gravitational force. The idea is that, to form a solar system (or a group of solar systems), a large amount has to come together; and in that case, it would have a significant mass, and significant forces would be acting.A small quantity of dust and gas will have a small gravitational force. The idea is that, to form a solar system (or a group of solar systems), a large amount has to come together; and in that case, it would have a significant mass, and significant forces would be acting.
The process of star formation begins in the universe within dense regions of gas and dust called molecular clouds. These clouds are where gravity pulls material together, eventually leading to the birth of a new star.
Gravity is crucial for the formation and structure of galaxies in our universe. It pulls together gas, dust, and stars, allowing them to clump together and form galaxies. Without gravity, galaxies would not be able to hold together and maintain their shape. Additionally, gravity plays a key role in the interactions between galaxies, influencing their movement and behavior within the universe.
The gravitational force is responsible for holding stars, gas, and dust together in space. This force pulls matter towards itself, allowing stars to form from clouds of gas and dust in nebulae. Additionally, the gravitational interactions between stars in galaxies help maintain the structure and cohesion of these celestial systems.
A protostar forms when gravity pulls the dust and gases in a nebula together.
Gravity pulls gas and dust by exerting a force that attracts particles towards each other. The larger the mass of an object, the stronger its gravitational pull. As a result, gas and dust particles are pulled towards regions of higher mass, causing them to clump together and form structures like stars and planets.
Gravitational force is what causes protostars to form. Gravity pulls together gas and dust in a molecular cloud, causing it to clump and collapse, eventually leading to the formation of a protostar.
Gravitational force pulled the particles of gas and dust together, causing the solar nebula to shrink and eventually form the solar system.
True.
Gravitational force pulls gas and dust particles together to form a nebula, while the outward pressure from gas particles pushing against each other (thermal pressure) prevents the nebula from collapsing under gravity. These two forces work together to stabilize a nebula.
Yes, that's correct! Stars are born when gravity causes gas and dust in a molecular cloud to collapse under their own weight. This collapse creates high pressures and temperatures in the core of the forming star, eventually igniting nuclear fusion and creating a stable star.
Gravitational force is the most responsible for the contraction of a gas cloud. As gravity pulls gas particles closer together, the cloud becomes denser and eventually leads to the formation of a star or stellar system.
The force that pulls together the matter in stars is gravity. It is the attractive force that arises between masses, causing gas and dust in a nebula to collapse under its own weight, leading to the formation of stars. As the material contracts, it heats up, eventually initiating nuclear fusion in the core, which produces the energy that powers the star. This balance between gravitational collapse and the outward pressure from fusion defines a star's stability and lifecycle.
The gravitational force pulled together swirling dust and gas in the early solar system, causing it to condense and form the Earth. This process is known as accretion.
Gas and dust in a nebula is disturbed by an outside force